Conceptual model

The conceptual model graphically represents how different stakeholders are articulated in the management of Andean SES in a context of global environmental change, and the related flows of information relevant to LTSEM (Figure 1). It includes 4 types of elements: systems, stakeholders (ie actors), processes, and their interactions, which were labeled and contrasted with existing LTSEM. This model is a conceptual tool with which to explore knowledge generation and governance of Andean SES and the equitable distribution of decision-making power, as it includes the main mechanisms that involve actors in research and knowledge production and its application to informed decision-making (Ariza-Montobbio and Cuvi 2020).

Andean social–ecological systems: Since societies depend on functioning ecosystems, and there is almost no ecosystem free from anthropic influence, it is essential to consider SES as a single unit of analysis (Petrosillo et al 2015), highlighting the complex interactions among biophysical and social components (Llambí and Llambí 2001; Pulver et al 2018). LTSEM of Andean systems depends on the identification of sensitive indicators and variables that are easy to measure and summarize the state of the SES (Turnhout et al 2007; Maggino and Zumbo 2012). For example, land-use and land-cover changes are key indicators of the effects of society on ecosystems (Potschin 2009); moreover, the provision of ecosystem services should be assessed with indicators quantifying their demand by society (Burkhard et al 2012).

Stakeholders: Three groups of actors interact with SES and are involved in their conceptualization, research, and monitoring (Young et al 2006). These groups, with different spheres of action (public and private) and scales (local to global), conceptualize and influence the system differently (Villamor et al 2014).

Processes: Andean SES are influenced by external factors such as climate change, telecouplings, and international legislation (Young et al 2006). The widespread manifestations of climate change (Parmesan 2006) are magnified in Andean SES because of the steep gradients and vulnerable social–ecosystems (Carey 2010). Telecouplings, the exchange of material, money, information, and people between distant systems (Hull and Liu 2018), increasingly influence Andean dynamics (eg farmers' decisions are influenced by global food markets; Llambí and Llambí 2001; Zimmerer et al 2018). Andean SES are also influenced by international legislation (ie agreements that regulate global relations and standards) driven by supranational organizations and conventions (eg United Nations Framework Convention on Climate Change, Intergovernmental Panel on Climate Change, Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services), intended to coordinate policies and minimize environmental injustices through the use of scientific information (Galaz et al 2012; Biermann et al 2016).

Characterization of monitoring efforts and identification of knowledge gaps

We analyzed 239 records of Andean LTSEM systems that resulted from 65 responses to the electronic survey, 124 published studies (from a total of 2443 publications) that passed scrutiny to ensure they addressed Andean LTSEM, and 50 active networks including Andean LTSEM systems (see  Appendixes S1 (mred-43-02-01_s01.xlsx),  S2 (mred-43-02-01_s01.xlsx), and  S3 (mred-43-02-01_s01.xlsx), respectively, Supplemental material,  https://doi.org/10.1659/mrd.2022.00018.S1). Each record was assigned one or more labels from the conceptual model, which allowed the fit between expected and existing monitoring efforts to be identified (Figure 1). We acknowledge that some monitoring efforts may be overrepresented (eg literature records or networks reported in the electronic survey). However, rather than performing a formal numerical analysis, we aimed to identify general patterns and research gaps, depicting the most infrequent (eg unpublished) labels within our conceptual model (eg those involving community-based approaches). The inclusion of all the available sources of information increased the likelihood of detecting these gaps. In addition, to visually assess the geographic representativeness of our study and of the LTSEM efforts in the region, we mapped every record (survey and published studies with known study area; Figure 2).

FIGURE 2

Geographic distribution of monitoring systems and temporal studies in the Andean region detected through electronic surveys and literature search. More than one location could be reported by an electronic survey.

Tabulating the labels assigned to the 239 LTSEM records and their graphical representation in the model (Figure 1) allowed us to identify research gaps around Andean SES dynamics. While most Andean LTSEM systems are related to environmental issues (235 records considered some environmental aspect, and 162 records did not consider any social aspect at all), with vegetation (n = 106) and climate (n = 100) being the most studied topics, social aspects were underrepresented. The effect of climate change was considered in 24 LTSEM systems, and international legislation was explicit in only 3 of these systems. Social–environmental studies were mainly focused on environmental quality (eg water and air conditions and urban solid wastes, n = 28), ecosystem services (n = 25; eg Fernández-Turiel et al 2003), or the quantification of land-use and land-cover changes (n = 24), and social aspects were usually disregarded (eg studies monitor environmental quality but do not explicitly quantify its effects on human health; Gramsch et al 2006). Only 4 of the identified LTSEMs focused solely on the social sciences (eg López-Sandoval and Maldonado 2019).

The disproportion between biophysical and social monitoring efforts is likely explained by methodological issues; some biophysical indicators have been used to summarize the state of an environmental system for a long time (eg rainfall, temperature). By contrast, the complexity and spatial variability of social systems and rapid technological and economic changes complicate the use of single indicators through time and space. Some additional aspects may contribute to the low representation of social aspects: (1) long-term social studies are seldom integrated into formal monitoring networks; (2) most social monitoring efforts are part of official statistics and programs such as national censuses, which were not detected explicitly in our search, although they are important sources of information for social–ecological research; and (3) social research is still infrequently integrated explicitly into social–environmental initiatives.

We found that community participation is scarce in the design, implementation, and operation of Andean LTSEM systems. Only one LTSEM, led by ProYungas Foundation in collaboration with governments and private companies, implemented codesigned research. This is also 1 of the 2 records that involved adaptive management (the other one is a risk management project in Colombia; Alzate Buitrago 2010). Participatory monitoring was more frequent in the implementation of Andean LTSEM; local communities participated in data collection for 9 LTSEM systems, but they were not involved in data analysis or interpretation. Most examples of community participation involved hydrological monitoring (eg Saavedra Daza et al 2020; Ulloa et al 2021) and took advantage of cell phone applications and web-based data collection (eg World Water Monitoring Challenge or the Litterati platform for surveying urban solid waste). Collaboration with local communities is deemed essential for successful social–environmental monitoring, as it promotes knowledge appropriation and increases the social relevance and applicability of research. However, the implementation of community participation poses big challenges, such as creating an effective dialogue between technical quantification and community knowledge. Participatory monitoring seems to be more likely when interests are transparent and homogeneous (eg private sector with clearly formulated goals or when some resource [eg water] is essential for the whole group) and when the participatory methods are accessible to local stakeholders (eg Litterati citizen science).

Although academics are frequently consulted by governments, and LTSEM systems depend on public funds, none of the records presented effective comanagement between academia and government; it is possible that the lack of common expectations, language, and time frames is a source of mutual distrust (Karam-Gemael et al 2018). Policymakers usually need rapid technical responses, while scientists are interested in novel and abstract problems, which are not always linked with social demands. Adaptive management (reported in 2 records; a single publication of Dallmeier et al 2002), considered an efficient tool to deal with uncertainty, implies a continuous reassessment of policies by contrasting expected and observed results (which need to be monitored). Most of the time, policymakers must address pressing problems and have no time or resources to monitor the impacts of implemented policies or revisit past problems that are assumed to be solved (eg crisis of water scarcity). This may raise a problem in coordinating and implementing effective adaptive management and policy implementation across scales (see Dupuits et al 2022). Even though policies are usually implemented in single geographic systems, their results could provide information across multiple spatiotemporal scales, a benefit that is usually beyond the scope of short-term policymaking. In this context, strengthening communication between policymakers and academics (eg comanagement of information platforms, explicit social–environmental science–policy dialogues) is key to reinforcing monitoring networks and regional political platforms and actions (eg within the framework of the Andean Mountain Initiative and other continental policy forums).

Collaborative networks promote the use of indicators in LTSEM, facilitating comparison and integration of different case studies (eg Carilla et al 2013; Cuesta et al 2020; Malizia et al 2020) and different areas of knowledge (Jimenez et al 2021). However, some constraints may arise in the selection of comparable variables because most LTSEM systems choose indicators based on specific social–ecological problems (eg changes in plant diversity, water pollution). Biophysical sciences have identified indicators that are easy to measure (eg the normalized difference vegetation index [NDVI] indicates vegetation activity, and the abundance of some organisms is deemed to be a good proxy of the health of an ecosystem; Linares Arias et al 2019). By contrast, social–environmental and social indicators enabling the comparison between sites are difficult to identify due to the diversity of social actors and conditions between Andean countries and landscapes (Bustamante et al 2014). The lack of core social indicators and networks focused on social issues reduces the opportunity to perform integrative analyses and create regional maps with adequate resolution. Although social studies might be underrepresented in our search, there are at least 2 objective aspects that make the integration of social studies more difficult. On the one hand, social issues are more complex than biophysical systems and present multiple nonlinear responses, so simple models incapable of extrapolation are generally less useful. On the other hand, the narrative approach, widely used in social areas, permits accurate characterization of complex systems, but their inclusion in quantitative comparisons and meta-analyses, particularly across wide spatial scales, is difficult.

Global changes affecting Andean SES highlight the importance of LTSEM because they generate nonanalogous conditions precluding the extrapolation of results. While most LTSEM systems only mention the potential effects of climate change on the Andean SES, some LTSEM systems assess these effects on environmental dynamics (eg Gloria or RBA networks; Morales et al 2015; Carilla et al 2018; Fadrique et al 2018). In contrast, we found no assessments of telecoupling effects, even though they are considered to be relevant drivers of Andean land-use changes (Aide et al 2019). International agreements advocate knowledge-based policies to handle problems that cannot be addressed by local governments (eg Aichi Biodiversity Targets; O'Connor et al 2015), and some LTSEM systems are considered to inform these policies: At least 3 networks were involved in the transference of knowledge to inform international agreements (Global Change in Mountain Regions or GLOCHAMORE, World Glacier Monitoring Service, and Global Cryosphere Watch, from the United Nations Educational, Scientific and Cultural Organization and World Meteorological Organization, which are specialized agencies of the United Nations). Information from LTSEM in the Andean region has informed international reports aimed at decision-makers such as those of the Intergovernmental Panel on Climate Change (eg Adler et al 2022). Recent efforts have also aimed to integrate LTSEM results into policy briefs and facilitate communication mechanisms of regional policy platforms such as the Andean Mountain Initiative (eg see iam-andes.org).

Research priorities for the development of an agenda for integrated social–environmental monitoring in the Andes and conclusions

Andean LTSEM systems constitute the best source of information to understand SES responses to unprecedented global changes and to increase their resilience. We combined a conceptual model representing interactions within Andean SES with an active search of LTSEM systems (through an electronic survey, literature review, and search of existing networks) to characterize monitoring efforts in terms of the topics addressed and the actors involved. This characterization of existing studies is necessary to coordinate efforts to fulfill existing knowledge gaps, facilitate information sharing, summarize complex processes at different spatial and temporal scales, and inform local social–environmental policies and international agreements.

The combination of our quantitative approach with the experts' opinions compiled from 2 interdisciplinary workshops allowed us to identify some research priorities for Andean LTSEM. We classified them into 5 categories (Table 1). (1) System conceptualization: The characterization of Andean SES, identifying main stakeholders, economic activities, ecological elements, and their interactions, should form the basis for analytical classifications of Andean SES (eg social–ecological land systems; Zarbá et al 2022). This classification, based on unified indicators and conceptual approaches, will permit more accurate integration of SES knowledge and the establishment of LTSEM at representative learning sites. (2) System functioning: The integration of systematic social–ecological information gathered through unified protocols with alternative proxies to fill geographic gaps (eg derived from remote sensing) and modeling approaches will allow a comprehensive understanding of Andean SES. The integration of monitoring approaches and protocols will allow the coordination of individual LTSEM systems and the analysis of different-scale processes that cannot be inferred from single case studies (eg Llambí et al 2019). (3) Influence of external dynamics: Although climate change is considered in Andean research, the effect of other global drivers of change, such as international trade, must be monitored. Since the responses of mountain SES to environmental changes are particularly complex in mountain landscapes, Andean LTSEM should actively provide information to global agreements and legislation. (4) Governance: The assessment of the effects of policies and management strategies through LTSEM and the implementation of participatory research through the use of new technologies will ensure a more socially relevant understanding and governance of Andean SES. The coordination of different LTSEM systems (eg through the consolidation of long-term integrated learning sites including multiple stakeholders) will increase Andean social–ecological resilience and sustainable management by facilitating the dialogue and flow of information between technicians and community-based knowledge systems. (5) Information accessibility: The growing availability of data and information (eg via integrated social–ecological indicator platforms; see Adaptación en las Alturas et al n.d.) will strengthen existing research networks, foster knowledge coproduction, support science–policy dialogue, and facilitate science-based governance. Making coherently gathered information accessible is necessary for regional synthesis analyses (eg Malizia et al 2020), which are key pieces in understanding complex systems.

TABLE 1

Research priorities for integrated monitoring of Andean SES identified from the perception of experts representing academia, government, and private sectors of different Andean countries (compiled during 2 interdisciplinary workshops), and from the analysis of different information sources on the state of the art of environmental and social monitoring along the Andes (surveys, literature, and networks) and the ways in which they are linked with the proposed conceptual model. Each priority was assigned with a recommendation type: “What” refers to the content of monitoring, “How” refers to the strategy, and “Why” refers to the purpose of the monitoring.

TABLE 1

Continued.

In summary, the foundation and the point of departure for the consolidation of the integrated monitoring agenda advocated here should be a reconceptualization of Andean SES, focusing on social–ecological interactions and considering the views of different stakeholders. It should also involve the integration of different disciplines and spatiotemporal scales. The identification of unified indicators leading to regional comparisons and providing relevant information for decision-making at multiple spatial scales remains a central challenge for LTSEM in the Andes. Research networks and long-term learning sites will play key roles in generating field information, measuring integrative indicators, and performing analytical syntheses (combining observational, experimental, and remote-sensing data), which can better inform science-based policies. Moreover, the participation of diverse stakeholders in knowledge production and system management is essential to strengthen governance and to promote the resilience of Andean SES to global changes that will increasingly influence these systems.